# SPDX-FileCopyrightText: 2014-2022 Fredrik Ahlberg, Angus Gratton,
# Espressif Systems (Shanghai) CO LTD, other contributors as noted.
#
# SPDX-License-Identifier: GPL-2.0-or-later

import struct
from typing import Dict

from .esp32 import ESP32ROM
from ..loader import ESPLoader
from ..util import FatalError, NotImplementedInROMError


class ESP32C3ROM(ESP32ROM):
    CHIP_NAME = "ESP32-C3"
    IMAGE_CHIP_ID = 5

    IROM_MAP_START = 0x42000000
    IROM_MAP_END = 0x42800000
    DROM_MAP_START = 0x3C000000
    DROM_MAP_END = 0x3C800000

    SPI_REG_BASE = 0x60002000
    SPI_USR_OFFS = 0x18
    SPI_USR1_OFFS = 0x1C
    SPI_USR2_OFFS = 0x20
    SPI_MOSI_DLEN_OFFS = 0x24
    SPI_MISO_DLEN_OFFS = 0x28
    SPI_W0_OFFS = 0x58

    BOOTLOADER_FLASH_OFFSET = 0x0

    # Magic values for ESP32-C3 eco 1+2, eco 3, eco 6, and eco 7 respectively
    CHIP_DETECT_MAGIC_VALUE = [0x6921506F, 0x1B31506F, 0x4881606F, 0x4361606F]

    UART_DATE_REG_ADDR = 0x60000000 + 0x7C

    UART_CLKDIV_REG = 0x60000014

    EFUSE_BASE = 0x60008800
    EFUSE_BLOCK1_ADDR = EFUSE_BASE + 0x044
    MAC_EFUSE_REG = EFUSE_BASE + 0x044

    EFUSE_RD_REG_BASE = EFUSE_BASE + 0x030  # BLOCK0 read base address

    EFUSE_PURPOSE_KEY0_REG = EFUSE_BASE + 0x34
    EFUSE_PURPOSE_KEY0_SHIFT = 24
    EFUSE_PURPOSE_KEY1_REG = EFUSE_BASE + 0x34
    EFUSE_PURPOSE_KEY1_SHIFT = 28
    EFUSE_PURPOSE_KEY2_REG = EFUSE_BASE + 0x38
    EFUSE_PURPOSE_KEY2_SHIFT = 0
    EFUSE_PURPOSE_KEY3_REG = EFUSE_BASE + 0x38
    EFUSE_PURPOSE_KEY3_SHIFT = 4
    EFUSE_PURPOSE_KEY4_REG = EFUSE_BASE + 0x38
    EFUSE_PURPOSE_KEY4_SHIFT = 8
    EFUSE_PURPOSE_KEY5_REG = EFUSE_BASE + 0x38
    EFUSE_PURPOSE_KEY5_SHIFT = 12

    EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT_REG = EFUSE_RD_REG_BASE
    EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT = 1 << 20

    EFUSE_SPI_BOOT_CRYPT_CNT_REG = EFUSE_BASE + 0x034
    EFUSE_SPI_BOOT_CRYPT_CNT_MASK = 0x7 << 18

    EFUSE_SECURE_BOOT_EN_REG = EFUSE_BASE + 0x038
    EFUSE_SECURE_BOOT_EN_MASK = 1 << 20

    PURPOSE_VAL_XTS_AES128_KEY = 4

    SUPPORTS_ENCRYPTED_FLASH = True

    FLASH_ENCRYPTED_WRITE_ALIGN = 16

    UARTDEV_BUF_NO = 0x3FCDF07C  # Variable in ROM .bss which indicates the port in use
    UARTDEV_BUF_NO_USB_JTAG_SERIAL = 3  # The above var when USB-JTAG/Serial is used

    RTCCNTL_BASE_REG = 0x60008000
    RTC_CNTL_SWD_CONF_REG = RTCCNTL_BASE_REG + 0x00AC
    RTC_CNTL_SWD_AUTO_FEED_EN = 1 << 31
    RTC_CNTL_SWD_WPROTECT_REG = RTCCNTL_BASE_REG + 0x00B0
    RTC_CNTL_SWD_WKEY = 0x8F1D312A

    RTC_CNTL_WDTCONFIG0_REG = RTCCNTL_BASE_REG + 0x0090
    RTC_CNTL_WDTWPROTECT_REG = RTCCNTL_BASE_REG + 0x00A8
    RTC_CNTL_WDT_WKEY = 0x50D83AA1

    MEMORY_MAP = [
        [0x00000000, 0x00010000, "PADDING"],
        [0x3C000000, 0x3C800000, "DROM"],
        [0x3FC80000, 0x3FCE0000, "DRAM"],
        [0x3FC88000, 0x3FD00000, "BYTE_ACCESSIBLE"],
        [0x3FF00000, 0x3FF20000, "DROM_MASK"],
        [0x40000000, 0x40060000, "IROM_MASK"],
        [0x42000000, 0x42800000, "IROM"],
        [0x4037C000, 0x403E0000, "IRAM"],
        [0x50000000, 0x50002000, "RTC_IRAM"],
        [0x50000000, 0x50002000, "RTC_DRAM"],
        [0x600FE000, 0x60100000, "MEM_INTERNAL2"],
    ]

    UF2_FAMILY_ID = 0xD42BA06C

    EFUSE_MAX_KEY = 5
    KEY_PURPOSES: Dict[int, str] = {
        0: "USER/EMPTY",
        1: "RESERVED",
        4: "XTS_AES_128_KEY",
        5: "HMAC_DOWN_ALL",
        6: "HMAC_DOWN_JTAG",
        7: "HMAC_DOWN_DIGITAL_SIGNATURE",
        8: "HMAC_UP",
        9: "SECURE_BOOT_DIGEST0",
        10: "SECURE_BOOT_DIGEST1",
        11: "SECURE_BOOT_DIGEST2",
    }

    def get_pkg_version(self):
        num_word = 3
        return (self.read_reg(self.EFUSE_BLOCK1_ADDR + (4 * num_word)) >> 21) & 0x07

    def get_minor_chip_version(self):
        hi_num_word = 5
        hi = (self.read_reg(self.EFUSE_BLOCK1_ADDR + (4 * hi_num_word)) >> 23) & 0x01
        low_num_word = 3
        low = (self.read_reg(self.EFUSE_BLOCK1_ADDR + (4 * low_num_word)) >> 18) & 0x07
        return (hi << 3) + low

    def get_major_chip_version(self):
        num_word = 5
        return (self.read_reg(self.EFUSE_BLOCK1_ADDR + (4 * num_word)) >> 24) & 0x03

    def get_flash_cap(self):
        num_word = 3
        return (self.read_reg(self.EFUSE_BLOCK1_ADDR + (4 * num_word)) >> 27) & 0x07

    def get_flash_vendor(self):
        num_word = 4
        vendor_id = (self.read_reg(self.EFUSE_BLOCK1_ADDR + (4 * num_word)) >> 0) & 0x07
        return {1: "XMC", 2: "GD", 3: "FM", 4: "TT", 5: "ZBIT"}.get(vendor_id, "")

    def get_chip_description(self):
        chip_name = {
            0: "ESP32-C3 (QFN32)",
            1: "ESP8685 (QFN28)",
            2: "ESP32-C3 AZ (QFN32)",
            3: "ESP8686 (QFN24)",
        }.get(self.get_pkg_version(), "unknown ESP32-C3")
        major_rev = self.get_major_chip_version()
        minor_rev = self.get_minor_chip_version()
        return f"{chip_name} (revision v{major_rev}.{minor_rev})"

    def get_chip_features(self):
        features = ["WiFi", "BLE"]

        flash = {
            0: None,
            1: "Embedded Flash 4MB",
            2: "Embedded Flash 2MB",
            3: "Embedded Flash 1MB",
            4: "Embedded Flash 8MB",
        }.get(self.get_flash_cap(), "Unknown Embedded Flash")
        if flash is not None:
            features += [flash + f" ({self.get_flash_vendor()})"]
        return features

    def get_crystal_freq(self):
        # ESP32C3 XTAL is fixed to 40MHz
        return 40

    def get_flash_voltage(self):
        pass  # not supported on ESP32-C3

    def override_vddsdio(self, new_voltage):
        raise NotImplementedInROMError(
            "VDD_SDIO overrides are not supported for ESP32-C3"
        )

    def read_mac(self, mac_type="BASE_MAC"):
        """Read MAC from EFUSE region"""
        if mac_type != "BASE_MAC":
            return None
        mac0 = self.read_reg(self.MAC_EFUSE_REG)
        mac1 = self.read_reg(self.MAC_EFUSE_REG + 4)  # only bottom 16 bits are MAC
        bitstring = struct.pack(">II", mac1, mac0)[2:]
        return tuple(bitstring)

    def get_flash_crypt_config(self):
        return None  # doesn't exist on ESP32-C3

    def get_secure_boot_enabled(self):
        return (
            self.read_reg(self.EFUSE_SECURE_BOOT_EN_REG)
            & self.EFUSE_SECURE_BOOT_EN_MASK
        )

    def get_key_block_purpose(self, key_block):
        if key_block < 0 or key_block > self.EFUSE_MAX_KEY:
            raise FatalError(
                f"Valid key block numbers must be in range 0-{self.EFUSE_MAX_KEY}"
            )

        reg, shift = [
            (self.EFUSE_PURPOSE_KEY0_REG, self.EFUSE_PURPOSE_KEY0_SHIFT),
            (self.EFUSE_PURPOSE_KEY1_REG, self.EFUSE_PURPOSE_KEY1_SHIFT),
            (self.EFUSE_PURPOSE_KEY2_REG, self.EFUSE_PURPOSE_KEY2_SHIFT),
            (self.EFUSE_PURPOSE_KEY3_REG, self.EFUSE_PURPOSE_KEY3_SHIFT),
            (self.EFUSE_PURPOSE_KEY4_REG, self.EFUSE_PURPOSE_KEY4_SHIFT),
            (self.EFUSE_PURPOSE_KEY5_REG, self.EFUSE_PURPOSE_KEY5_SHIFT),
        ][key_block]
        return (self.read_reg(reg) >> shift) & 0xF

    def is_flash_encryption_key_valid(self):
        # Need to see an AES-128 key
        purposes = [
            self.get_key_block_purpose(b) for b in range(self.EFUSE_MAX_KEY + 1)
        ]

        return any(p == self.PURPOSE_VAL_XTS_AES128_KEY for p in purposes)

    def change_baud(self, baud):
        ESPLoader.change_baud(self, baud)

    def uses_usb_jtag_serial(self):
        """
        Check the UARTDEV_BUF_NO register to see if USB-JTAG/Serial is being used
        """
        if self.secure_download_mode:
            return False  # Can't detect USB-JTAG/Serial in secure download mode
        return self.get_uart_no() == self.UARTDEV_BUF_NO_USB_JTAG_SERIAL

    def disable_watchdogs(self):
        # When USB-JTAG/Serial is used, the RTC WDT and SWD watchdog are not reset
        # and can then reset the board during flashing. Disable or autofeed them.
        if self.uses_usb_jtag_serial():
            # Disable RTC WDT
            self.write_reg(self.RTC_CNTL_WDTWPROTECT_REG, self.RTC_CNTL_WDT_WKEY)
            self.write_reg(self.RTC_CNTL_WDTCONFIG0_REG, 0)
            self.write_reg(self.RTC_CNTL_WDTWPROTECT_REG, 0)

            # Automatically feed SWD
            self.write_reg(self.RTC_CNTL_SWD_WPROTECT_REG, self.RTC_CNTL_SWD_WKEY)
            self.write_reg(
                self.RTC_CNTL_SWD_CONF_REG,
                self.read_reg(self.RTC_CNTL_SWD_CONF_REG)
                | self.RTC_CNTL_SWD_AUTO_FEED_EN,
            )
            self.write_reg(self.RTC_CNTL_SWD_WPROTECT_REG, 0)

    def _post_connect(self):
        if not self.sync_stub_detected:  # Don't run if stub is reused
            self.disable_watchdogs()

    def check_spi_connection(self, spi_connection):
        if not set(spi_connection).issubset(set(range(0, 22))):
            raise FatalError("SPI Pin numbers must be in the range 0-21.")
        if any([v for v in spi_connection if v in [18, 19]]):
            print(
                "WARNING: GPIO pins 18 and 19 are used by USB-Serial/JTAG, "
                "consider using other pins for SPI flash connection."
            )


class ESP32C3StubLoader(ESP32C3ROM):
    """Access class for ESP32C3 stub loader, runs on top of ROM.

    (Basically the same as ESP32StubLoader, but different base class.
    Can possibly be made into a mixin.)
    """

    FLASH_WRITE_SIZE = 0x4000  # matches MAX_WRITE_BLOCK in stub_loader.c
    STATUS_BYTES_LENGTH = 2  # same as ESP8266, different to ESP32 ROM
    IS_STUB = True

    def __init__(self, rom_loader):
        self.secure_download_mode = rom_loader.secure_download_mode
        self._port = rom_loader._port
        self._trace_enabled = rom_loader._trace_enabled
        self.cache = rom_loader.cache
        self.flush_input()  # resets _slip_reader


ESP32C3ROM.STUB_CLASS = ESP32C3StubLoader
